Internal tank augers for air seeder hoppers

ABSTRACT

An air seeder is provided having at least one container with a trough in the bottom floor. Preferably, the floor is formed with a v-shaped configuration converging at a metering mechanism. An auger is rotatably mounted in the trough to move particulate material to the metering mechanism located at a distal end of the container. The auger is powered by a motor mounted on the distal end of the auger opposite the metering mechanism. A remote fan mechanism is provided to deliver a supply of air to the metering mechanism through a pair of conveying tubes. Optionally, a sensor is provided to control the operation of the auger so that the auger only operates when it is needed.

FIELD OF THE INVENTION

[0001] The present invention relates generally to an agriculturalimplement, such as an air cart forming part of an air seeding implementfor planting seed and fertilizer into the ground. In particular, thepresent invention relates to the use of augers in low incline air seedertanks to transfer product such as seed or fertilizer to a meteringmechanism for disposition to the ground.

BACKGROUND OF THE INVENTION

[0002] Air carts for use on agricultural implements are well known.Typically, these air carts are used as part of an air seeder in whichseeds, fertilizer and herbicides are deposited onto and into the groundduring the planting operation. Air seeders and other seeding devices arecommonly towed by tractors to apply seed or fertilizer, or bothsimultaneously, to a field. For example, an air seeder may be towed incombination with a tilling implement, one behind the other, to place theseed and fertilizer under the surface of the soil. Generally, air cartsare in either a two container or three container configuration. The twocontainer configuration is used to carry a supply of seeds andfertilizer for planting into the ground. The three containerconfiguration can be used to carry an additional element, such as anherbicide, to be deposited on the ground. The three containerconfiguration, however, can also be used to carry only one or twomaterials in whatever amounts are desired.

[0003] Air seeders also typically include a metering system fordispensing product from the tanks and a pneumatic distribution systemfor delivering the product from the tank to the soil. The tanks of theair seeders are formed with bottom surfaces that slope downward at theangle of repose for the product toward the metering mechanism. Gravity,in combination with the vibrations and movement of the air seeder, actto move the grain from the perimeter of the tank toward the meteringmechanism located at the center of the tank.

[0004] Such movement of the product can be inefficient, and seed and/orfertilizer is often left behind when the volume in the tank becomes low.While this small amount of seed/or fertilizer does not substantiallyinterfere with the ongoing operations of the air seeder, the seed orfertilizer that is left in the grain tank over extended periods of time,such as during storage of the air seeder between seasons, will likelyspoil. This spoiled product will then be discharged from the air seederthe next time it is used, leading to contamination of the newly addedproduct. Moreover, the spoiling or rotting process of the seed orfertilizer in the air seeder tank can be corrosive to the air seeder.Over time, the air seeder tank can be damaged and require repair.Additionally, any product that is left in the tank when the tank isswitched to a different product will exit the air seeder with that newproduct. For example, if the tank has been used to dispense fertilizer,fertilizer will remain in the tank and will be intermingled with, forexample, seeds when the tank is next used. This could be damaging to theseeds. Moreover, operators of air seeders demand that almost all productdrain evenly from the tank with each use so that greater fieldefficiency can be achieved.

[0005] Further, it is desirable to increase the volume of the air seederhopper so that more ground can be covered without having to stop andre-fill the tanks. However, if larger tanks are employed, the air seederbecomes unstable due to an excessive center of gravity. Additionally, ina large capacity two tank system, the optimal design would typicallyplace the rear metering mechanism rearward over the axle. However, thiscauses interference both with clean out and with the location of themetering mechanism in a gravity fed tank. In order to translate theslopes and drain the tanks to one metering location, the tanks must bemoved forward, thereby increasing the frame length and making the tankseven more unstable.

[0006] Accordingly, it would be desirable to provide a large capacityair seeder hopper which can carry a large volume of product andefficiently transport the product to the metering mechanism and overcomethe aforementioned disadvantages of the current state of the art.

SUMMARY OF THE INVENTION

[0007] Accordingly, an important object of the present invention is toprovide an auger for use in air seeder tanks to transfer particulatematerial such as seed or fertilizer to a metering mechanism fordisposition to the ground.

[0008] It is another object of the present invention to provide an augerlocated along a trough incorporated into the bottom floor of the tank ofthe air seeder.

[0009] It is yet another object of this invention to locate the reartank metering mechanism forward of the rear axle and in close proximityto the metering mechanism of the front tank.

[0010] It is a further object of the present invention initiation toprovide sensors to indicate the grain level within the tanks or to sensea shortage of grain at the metering mechanism.

[0011] It is another object of the present invention provide a compacttank design to limit the physical tank size.

[0012] It is yet another object of this invention to provide motors toindividually power each auger.

[0013] It is a further object of the present invention to reduce hopperdepth.

[0014] It is an advantage of the present invention that the center ofgravity in the tank is lowered, which stabilizes the air seeder.

[0015] It is another advantage of the present invention that the augerstransfer the particulate material to the metering mechanisms only whenrequired.

[0016] It is a further advantage of the present invention that theindividual augers can be lifted to provide for a fast and easy cleanout.

[0017] It is a feature of the present invention that the floor of eachindividual tank is formed with a v-shaped configuration that convergesinto the metering mechanism.

[0018] It is another feature of this invention that the individualcontainers can be molded from noncorrosive plastic or single sheetmetal.

[0019] It is yet another feature of the present invention that the slopeof the floor of the individual tanks is shallow.

[0020] It is a further feature of this invention that the augers can beinitiated in a response to a lowered torque as the particulate materialdrains from the flightings.

[0021] It is another feature of the present invention that the meteringmechanisms are not centered on each tank.

[0022] It is still another feature of this invention to providecontainers for an air seeder that are durable in construction,inexpensive to manufacture, easy to maintain, and simple and effectivein use.

[0023] These and other objects, features, and advantages areaccomplished according to the present invention by providing an airseeder having a frame, a pair of ground engaging wheels, a meteringmechanism, and at least one container having at least one troughincorporated into the bottom floor with an auger rotatably mounted ineach of the troughs for transporting particulate material along thefloor of the container to the metering mechanism.

[0024] The foregoing and other objects, features, and advantages of theinvention will appear more fully hereinafter from a consideration of thedetailed description that follows, in conjunction with the accompanyingsheets of drawings. It is to be expressly understood, however, that thedrawings are for illustrative purposes and are not to be construed asdefining the limits of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

[0025] The advantages of this invention will be apparent uponconsideration of the following detailed disclosure of the invention,especially when taken in conjunction with the accompanying drawingswherein:

[0026]FIG. 1 is a side elevational of a prior art air seeder mechanismof a general type in which the principles of the present invention canbe incorporated;

[0027]FIG. 2 is an enlarged partial side elevational view of an airseeder hopper incorporating the principles of the present invention,portions of the frame and hitch being removed for purposes of clarity;

[0028]FIG. 3 is a partial front elevational view of the air seederhopper corresponding to FIG. 1;

[0029]FIG. 4 is a partial underside perspective view of the air seederhopper corresponding to FIGS. 2 and 3;

[0030]FIGS. 5a-5 g are schematic perspective views of the hopper;

[0031]FIG. 6 is a partial perspective view of an air seeder hoppershowing the location of an optical sensor;

[0032]FIG. 7 is a schematic elevational view of an air seeder hopperillustrated in FIG. 2 showing the auger in a working position; and

[0033]FIG. 8 is a schematic elevational view of an air seeder hopperillustrated in FIG. 2 showing the auger in a clean out position.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0034] Referring now to FIGS. 1-4, the details of an air seeder hopperincorporating the principles of the present invention can best be seen.The air cart 10 preferably has a large capacity tank 11 of one orpreferably two container configuration. The two individual containers12, 14, as shown in FIGS. 2-4, are mounted on a frame mechanism 15 whichis supported by ground engaging wheels 16 for mobile movement over theground. Each container 12, 14 is preferably formed from molded plasticand is capable of being pressurized. Preferably, each container 12, 14is capable of being pressurized at a different operating pressure fromthe other container. Furthermore, each container 12, 14 must be capableof operating under different levels of fullness. For example, fertilizerin one container and seed in another container will not necessarilyempty at the same rate, particularly for different types of seeds thatcan be planted.

[0035] Each container 12, 14 is provided with a metering mechanism 15 ofgenerally conventional configuration, but positioned near a distal endof the container. Because of the large capacity of the container, andthe requisite positioning of the metering mechanism 15 at the interiorend of the container, so as to be positionable adjacent of the meteringmechanism of the opposing container near the center of the tank, theslope of the floor of the individual containers 12, 14 is shallow, oreven flat. To move particulate material, such as fertilizer or seed,within the container to the metering mechanism 15, an auger 20 islocated along a trough 18 incorporated into the bottom floor of theindividual container 12, 14.

[0036] A supply of air from a remote fan mechanism as represented inFIG. 1 can be delivered to the metering mechanism 15 by conveying tubes22 that can pass at least partially internally of the individualcontainer 12, 14, as is shown in FIGS. 2 and 3. Preferably the airsupply for both metering mechanisms for the two containers 12, 14 willcome from a single fan mechanism (not shown) and be distributed toappropriately placed conveying tubes 22 to receive particulate materialdelivered through the metering mechanisms 15 for conveyance thereof tothe planters as shown in FIG. 1. Since both containers 12, 14 arecommonly manufactured, the conveying tubes 22 may be present in the rearcontainer 14, although not be connected to a fan mechanism to provide asupply of air.

[0037] As is best seen in FIGS. 3, 4 and 5 a-5 g, the floor of eachindividual container is formed with a double v-shaped configurationconverging into the metering mechanism 15. At the lower apex of eachv-shaped configuration, a trough 18 is provided in which an auger 20 isrotatably mounted to convey grain or other particulate material alongthe bottom of the floor into the metering mechanism 15. Preferably,there is an auger 20 located in each of the troughs 18 in the containers12, 14. The v-shaped configuration of the floor facilitates the movementof particulate material into the auger 20 for conveyance to the meteringmechanism 15. As is best seen in FIGS. 4, 7 and 8, each auger 20 isindividually powered by a motor 21 mounted on the distal end of theauger 20 compared to the metering mechanism 15. Preferably, these motorsare hydraulically driven; however, they could be driven electrically orpneumatically as well.

[0038] Preferably the floor of the container is sloped toward themetering mechanism 15 from the distal end thereof to enable a gravityflow of product within the container into the metering mechanism 15. Theaugers 20 in such a configuration will be utilized only to conveyproduct within the container as a result of insufficient gravity flowinto the metering mechanism. Thus, the augers 20 are rotated by themotors 21 only when required to convey product into the meteringmechanisms 15.

[0039] To control the operation of the individual augers 20, a sensor 19is incorporated into a product supply box 17 forming part of themetering mechanism 15. When the sensor 19 indicates a shortage ofproduct to be dispensed through the metering mechanism 15, a controller13 initiates rotation of the motors 21 to convey product from the hopperinto the product supply box 17 of the metering mechanism 15, thusfilling the metering mechanism 15 as needed to maintain proper operationthereof. When a sufficient supply of product is present in the meteringmechanism 15, the sensor 19 stops the rotation of the auger 20.

[0040] Alternatively, as illustrated in FIG. 6, initiation of the driveof the augers 20 can be the response of a signal from an optical sensor29 indicating the grain level within the container or by sensing loweredtorque requirements to effect rotation of the auger as grain, or otherproducts, drains from above the flightings of the augers.

[0041] Although the slope of the container 12, 14 and the use of augers20 removes most of the particulate material from the containers 12, 14during operation, some residual particulate material remains in thetank. As shown in FIG. 7, when the auger 20 is in the working position,the auger 20 is located at the bottom of trough 18. However, asillustrated in FIG. 8, to completely clean out the containers 12, 14,the augers 20 are lifted at the non-driving end and the containers 12,14 are manually swept clean.

[0042] In a preferred embodiment, the augers 20 are released by an easyrelease mechanism 30, as illustrated in FIGS. 6-8. The easy releasemechanism 30 includes a u-shaped bracket 31 having a pair of upwardlyextending arms with holes therein to receive a pin 33. When the pin 33is inserted through the holes, the easy release mechanism 30 is in aclosed and locked position. As a result, the auger 20 remains placed inthe trough 18 in the working position. To clean out the containers 12,14, the operator simply removes the pin 33 from the u-shaped bracket 31and raises the auger 20 for manual clean out as described above.

[0043] The invention of this application has been described above bothgenerically and with regard to specific embodiments. Although theinvention has been set forth in what is believed to be the preferredembodiments, a wide variety of alternatives known to those of skill inthe art can be selected within the generic disclosure. The invention isnot otherwise limited, except for the recitation of the claims set forthbelow.

Having thus described the invention, what is claimed is:
 1. In an airseeder having a frame, a pair of ground engaging wheels, at least onecontainer having an outer end wall, an opposite inner end wall, and sidewalls connecting the outer end wall and the opposite inner end wall, anda metering mechanism for dispensing particulate product from said atleast one container, the improvement comprising: said at least onecontainer having a trough incorporated into a bottom floor and an augerrotatably mounted in said trough for transporting said particulatematerial along said floor to said metering mechanism.
 2. The air seederof claim 1, further comprising a motor mounted on a distal end of saidauger relative to said metering mechanism to rotate said auger andconvey said particulate material to said metering mechanism.
 3. The airseeder of claim 2, wherein said metering mechanism is located at an endof said container.
 4. The air seeder of claim 3, wherein said floor isshaped in a v-shaped configuration converging at said meteringmechanism.
 5. The air seeder of claim 4, wherein said container isformed in a double v-shaped configuration to facilitate movement ofparticulate material into the auger for conveyance of said particulatematerial to said metering mechanism.
 6. The air seeder of claim 5,wherein said trough is located in a lower apex of each of said v-shapedconfigurations, each said trough having an auger rotatably mountedtherein for transporting said particulate material along said floor tosaid metering mechanism.
 7. The air seeder of claim 3, furthercomprising: a sensor in said metering mechanism to detect a shortage ofsaid particulate material being dispensed through said meteringmechanism, and a controller to initiate rotation of said auger to conveyparticulate material from the container to fill said metering mechanism.8. The air seeder of claim 7, wherein said sensor stops said motor whena sufficient amount of said particulate material is present in saidmetering mechanism.
 9. The air seeder of claim 3, further comprising anoptical sensor located in said container to sense a level of particulatematerial within said container, said optical sensor triggering the startof said motor and subsequent rotation of said auger to deliver saidparticulate material to said metering mechanism.
 10. The air seeder ofclaim 3, further comprising a fan mechanism and a pair of conveyingtubes that pass at least partially internally of said container fordelivering air to said metering mechanism.
 11. The air seeder of claim10, wherein said container is formed of molded plastic.
 12. The airseeder of claim 1, wherein said air seeder includes a first containerhaving a first metering mechanism and a second container having a secondmetering mechanism, said first metering mechanism being located in closeproximity to said second metering mechanism.
 13. The air seeder of claim3, wherein said auger is initiated in response to lowered torque toeffect rotation of said auger as said particulate product drains fromsaid container.
 14. An air seeder comprising: a frame, a pair of groundengaging wheels, a first container having an outer end wall, an oppositeinner end wall, and side walls connecting the outer end wall and theopposite inner end wall, a second container having an outer end wall, anopposite inner end wall, and side walls connecting the outer end walland the opposite inner end wall, a first and second metering mechanismfor distributing particulate material to the ground, said first meteringmechanism being located in close proximity to said second meteringmechanism, a trough incorporated into a bottom floor of each of saidfirst and second containers, an auger rotatably mounted in each saidtrough for transporting said particulate material along thecorresponding said floor to the corresponding said metering mechanisms,and a motor for rotating each respective said auger to convey saidparticulate material to the corresponding said metering mechanism, eachsaid motor being initiated only when required to convey said particulatematerial to the respective said first and second metering mechanisms.15. The air seeder of claim 14, wherein said floor of said first andsecond containers is shaped in a v-shaped configuration converging atsaid first and second metering mechanisms respectively.
 16. The airseeder of claim 14, further comprising a fan mechanism and a pair ofconveying tubes that pass at least partially internally in at least oneof said containers for delivering air to said metering mechanisms. 17.The air seeder of claim 15, wherein said first and second containers areformed in a double v-shaped configuration to facilitate movement ofparticulate material into said auger for conveyance of said particulatematerial to said first and second metering mechanisms.
 18. The airseeder of claim 17, wherein said troughs are located in a lower apex ofeach of said v-shaped configurations, each said trough having an augerrotatably mounted therein for transporting said particulate materialalong said floor to said metering mechanism.
 19. The air seeder of claim14, wherein said initiation of said motor occurs when a sensor locatedin each of said first and second metering mechanisms detects a shortageof said particulate material to be dispensed through the respective saidfirst or second metering mechanism.
 20. The air seeder of claim 14,wherein each said container includes an optical sensor to detect a levelof particulate material within the respective container, said initiationof said motor and subsequent rotation of the corresponding said augeroccurring when one of said optical sensors detects a decreased level ofparticulate material in said container.
 21. The air seeder of claim 14,wherein said auger is initiated in response to a sensed lowered torqueto effect rotation of said auger as said particulate product drains fromsaid container.
 22. A method of conveying particulate material from anair seeder having a container for holding a supply of said particulatematerial and a metering mechanism for dispensing said particulatematerial, comprising the steps of: allowing said particulate materialwithin said container to drain by gravity into said metering mechanism;sensing a shortage of supply of said particulate material to bedispensed from said metering mechanism as a result of said allowingstep; and rotating an auger housed within a trough in a floor member ofsaid container to deliver any remaining particulate material within saidcontainer to said metering mechanism.
 23. The method of claim 22,wherein said sensing step includes the step of sensing a lack ofsufficient supply of particulate material within said meteringmechanism.
 24. The method of claim 22, wherein said sensing stepincludes the step of sensing a predetermined level of supply ofparticulate material within said container with an optical sensor. 25.The method of claim 22, wherein said sensing step includes the step ofsensing a lowered torque requirement to effect rotation of said auger.26. The method of claim 22, wherein said allowing step is enhanced bythe shape of said floor of said container to drain particulate materialboth vertically and horizontally into said metering mechanism.
 27. Themethod of claim 26, wherein said rotating step is accomplished byinitiating a motor connected to an end of said auger remote from saidmetering mechanism.
 28. The method of claim 27, wherein said air seederis provided with at least two containers for housing differentparticulate material, said allowing, sensing and rotating steps beingaccomplished independently within each respective said container.